Your search keyword '"Schipper NRM"' showing total 3 results

1. Functionalized Substrates for Reduced Nonradiative Recombination in Metal-Halide Perovskites.

Author

Aalbers GJW, Remmerswaal WHM, van den Heuvel RHC, Bellini L, Kessels LM, Weijtens CHL, Schipper NRM, Wienk MM, and Janssen RAJ

Abstract

Reducing nonradiative recombination is crucial for minimizing voltage losses in metal-halide perovskite solar cells and achieving high power conversion efficiencies. Photoluminescence spectroscopy on complete or partial perovskite solar cell stacks is often used to quantify and disentangle bulk and interface contributions to nonradiative losses. Accurately determining the intrinsic loss in a perovskite layer is key to analyzing the origins of nonradiative recombination and developing defect engineering strategies. Here, we study perovskite films on glass and indium-tin-oxide-covered glass substrates, functionalized with a range of different molecules, using absolute and transient photoluminescence. We find that grafting these substrates with 1,6-hexylenediphosphonic acid (HDPA) effectively reduces the nonradiative losses in perovskite films for a series of perovskite semiconductors with bandgaps ranging from 1.26 to 2.28 eV. The results suggest that perovskites processed on HDPA-functionalized substrates suffer the least from nonradiative recombination and thus approach the properties of a defect-free semiconductor.

Published

2025

2. Performance and stability analysis of all-perovskite tandem photovoltaics in light-driven electrochemical water splitting.

Author

Wang J, Branco B, Remmerswaal WHM, Hu S, Schipper NRM, Zardetto V, Bellini L, Daub N, Wienk MM, Wakamiya A, Snaith HJ, and Janssen RAJ

Abstract

All-perovskite tandem photovoltaics are a potentially cost-effective technology to power chemical fuel production, such as green hydrogen. However, their application is limited by deficits in open-circuit voltage and, more challengingly, poor operational stability of the photovoltaic cell. Here we report a laboratory-scale solar-assisted water-splitting system using an electrochemical flow cell and an all-perovskite tandem solar cell. We begin by treating the perovskite surface with a propane-1,3-diammonium iodide solution that reduces interface non-radiative recombination losses and achieves an open-circuit voltage above 90% of the detailed-balance limit for single-junction solar cells between the bandgap of 1.6-1.8 eV. Specifically, a high open-circuit voltage of 1.35 V and maximum power conversion efficiency of 19.9% are achieved at a 1.77 eV bandgap. This enables monolithic all-perovskite tandem solar cells with a 26.0% power conversion efficiency at 1 cm 2 area and a pioneering photovoltaic-electrochemical system with a maximum solar-to-hydrogen efficiency of 17.8%. The system retains over 60% of its peak performance after operating for more than 180 h. We find that the performance loss is mainly due to the degradation of the photovoltaic component. We observe severe charge collection losses in the narrow-bandgap sub-cell that can be attributed to the interface degradation between the narrow-bandgap perovskite and the hole-transporting layer. Our study suggests that developing chemically stable absorbers and contact layers is critical for the applications of all-perovskite tandem photovoltaics., Competing Interests: Competing interests: H.J.S. is cofounder and CSO of Oxford PV Ltd. A.W. is co-founder and CSO of Enecoat Technologies Co., Ltd. All other authors declare no competing interests., (© 2024. The Author(s).)

Published

2025

3. Steering perovskite precursor solutions for multijunction photovoltaics.

Author

Hu S, Wang J, Zhao P, Pascual J, Wang J, Rombach F, Dasgupta A, Liu W, Truong MA, Zhu H, Kober-Czerny M, Drysdale JN, Smith JA, Yuan Z, Aalbers GJW, Schipper NRM, Yao J, Nakano K, Turren-Cruz SH, Dallmann A, Christoforo MG, Ball JM, McMeekin DP, Zaininger KA, Liu Z, Noel NK, Tajima K, Chen W, Ehara M, Janssen RAJ, Wakamiya A, and Snaith HJ

Abstract

Multijunction photovoltaics (PVs) are gaining prominence owing to their superior capability of achieving power conversion efficiencies (PCEs) beyond the radiative limit of single-junction cells 1-8 , where improving narrow bandgap tin-lead perovskites is critical for thin-film devices 9 . With a focus on understanding the chemistry of tin-lead perovskite precursor solutions, we herein find that Sn(II) species dominate interactions with precursors and additives and uncover the exclusive role of carboxylic acid in regulating solution colloidal properties and film crystallisation, and ammonium in improving film optoelectronic properties. Materials that combine these two function groups, amino acid salts, considerably improve the semiconducting quality and homogeneity of perovskite films, surpassing the effect of the individual functional groups when introduced as part of separate molecules. Our enhanced tin-lead perovskite layer allows us to fabricate solar cells with PCEs of 23.9, 29.7 (certified 29.26%), and 28.7% for single-, double-, and triple-junction devices, respectively. Our 1-cm 2 triple-junction devices show PCEs of 28.4% (certified 27.28%). Encapsulated triple-junction cells maintain 80% of their initial efficiencies after 860 h maximum power point tracking in ambient. We further fabricate quadruple-junction devices and obtain PCEs of 27.9% with the highest open-circuit voltage of 4.94 V. This work establishes a new benchmark for multijunction PVs., (© 2024. The Author(s), under exclusive licence to Springer Nature Limited.)

Published

2024